Complementarity relations for quantum coherence

TL;DR

This paper explores the mathematical relationships and bounds between different measures of quantum coherence, especially in mutually unbiased bases, and discusses their operational implications in quantum information tasks.

Contribution

It introduces new bounds and relations for quantum coherence measures, including a complementarity relation for qubits and links to G-asymmetry, advancing understanding of coherence quantification.

Findings

Derived tight bounds on coherence in mutually unbiased bases

Established a complementarity relation for qubit coherences

Connected relative entropy of coherence to G-asymmetry and operational tasks

Abstract

Various measures have been suggested recently for quantifying the coherence of a quantum state with respect to a given basis. We first use two of these, the l_1-norm and relative entropy measures, to investigate tradeoffs between the coherences of mutually unbiased bases. Results include relations between coherence, uncertainty and purity; tight general bounds restricting the coherences of mutually unbiased bases; and an exact complementarity relation for qubit coherences. We further define the average coherence of a quantum state. For the l_1-norm measure this is related to a natural 'coherence radius' for the state, and leads to a conjecture for an l_2-norm measure of coherence. For relative entropy the average coherence is determined by the difference between the von Neumann entropy and the quantum subentropy of the state, and leads to upper bounds for the latter quantity. Finally, we point out that the relative entropy of coherence is a special case of G-asymmetry, which immediately yields several operational interpretations in contexts as diverse as frame-alignment, quantum communication and metrology, and suggests generalising the property of quantum coherence to arbitrary groups of physical transformations.